bimorph

简明释义

[ˈbaɪmɔːf][ˈbaɪmɔf]

n. 双压电晶片零件(等于 bimorph cell)

英英释义

A bimorph is a type of actuator or sensor that consists of two layers of material, typically with different thermal expansion properties, which bend or deform when subjected to temperature changes.

双形体是一种执行器或传感器,由两层具有不同热膨胀特性的材料组成,当受到温度变化时会弯曲或变形。

单词用法

bimorph structure

双形态结构

bimorph actuator

双形态驱动器

bimorph material

双形态材料

design a bimorph

设计一个双形态

analyze bimorph behavior

分析双形态行为

utilize bimorph technology

利用双形态技术

同义词

bimodal

双模态的

The bimodal distribution of the data suggests two underlying processes.

数据的双模态分布暗示着两个潜在的过程。

dual-form

双形式的

The dual-form design allows for versatility in application.

双形式设计使得应用更加多样化。

two-part

两部分的

This two-part structure is essential for understanding the system's behavior.

这种两部分结构对理解系统的行为至关重要。

反义词

unimorph

单形态

The unimorph structure is simpler and easier to manufacture.

单形态结构更简单,制造起来更容易。

monomorph

单一形态

In contrast to bimorph devices, monomorphs lack the ability to change shapes.

与双形态设备相比,单一形态缺乏改变形状的能力。

例句

1.In order to describe the characteristics of piezoelectric bimorph, properties of PZT film are studied by SEM and XRD.

为了更好地研究双晶片的特性,利用扫描电镜(sem)和x -射线衍射(XRD)技术,对PZT薄膜的特性进行了较为详细的研究。

2.Finally, the effect of the impedance, standing for a storage circuit, and the concentrated mass at the free end of the bimorph on the harvester performance is discussed in detail.

最后还详细讨论了储能电路的阻抗,自由端悬挂的集中质量对俘能器性能的影响规律。

3.A new precise actuator with 2 degrees of freedom for translational and rotational motions actuated by the impact force of an end-loaded piezoelectric bimorph cantilever was proposed.

研制了一种以自由端带有集中质量的悬臂式压电双晶片为驱动单元、具有移动和旋转二自由度的惯性冲击式精密驱动器。

4.This paper describes principles, configurations, circuitry and properties of disk and bimorph piezoelectric linear data accelerometers.

本文叙述圆片式和双晶片式压电线性数字加速度表的原理、结构、电路和性能。

5.Shear force detection is carried out by using a symmetric piezoelectric bimorph sensor, which provides an easy way not only for probe-surface distance control but also for imaging.

利用结构对称的双压电陶瓷传感器实现了切变力的探测,并为探针-样品的间距控制与成像提供了一种有效手段。

6.The driving system of the speaker is constructed by a circular PZT bimorph, which is clamped on its boundary, An elastical coupling element is utilized between the bimorph and the speaker cone.

扬声器的驱动元件是边缘固定的圆形PZT 双型弯曲振子,振动——辐射元件是圆锥形纸盆,这两部分之间采用弹性耦合。

7.The driving system of the speaker is constructed by a circular PZT bimorph, which is clamped on its boundary, An elastical coupling element is utilized between the bimorph and the speaker cone.

扬声器的驱动元件是边缘固定的圆形PZT 双型弯曲振子,振动——辐射元件是圆锥形纸盆,这两部分之间采用弹性耦合。

8.A new type of the PZT driving device to realize the planar movement by using the bimorph oscillator as the driver was presented.

采用双压电晶片振子为移动机构的驱动源,提出可以实现二维平面移动的新型压电驱动机构。

9.PZT micro -force sensors were calibrated by bimorph and electronic balance in static state and by bimorph and charge amplifier in dynamic state, small signal was tested by amplifier.

采用双晶片探头和电子天平对PZT微力传感器进行静态力标定,进而利用双晶片探头和电荷放大器对PZT微力传感器进行准静态标定,微小信号检测通过锁相放大器来实现。

10.The bimorph technology is crucial in creating advanced sound devices.

在制造先进声音设备时,bimorph 技术是至关重要的。

11.The bimorph sensor can detect temperature changes effectively.

bimorph 传感器能够有效检测温度变化。

12.In the latest robotics research, a bimorph structure was used to enhance movement precision.

在最新的机器人研究中,使用了bimorph 结构来增强运动精度。

13.The engineer designed a bimorph actuator that can bend in two directions.

工程师设计了一种可以向两个方向弯曲的bimorph 驱动器。

14.Using a bimorph design allows for more flexible applications in devices.

采用bimorph 设计可以使设备在应用上更加灵活。

作文

In the realm of materials science and engineering, the term bimorph refers to a structure that consists of two distinct layers made from different materials. These materials are often chosen for their contrasting properties, such as thermal expansion or electrical conductivity. The interaction between these two layers allows the bimorph to exhibit unique behaviors, making it a fascinating subject for research and application. For instance, bimorph actuators are commonly used in devices that require precise movement, such as printers and sensors. When an electric current is applied, one layer expands while the other contracts, causing the entire structure to bend. This principle is not only applicable in engineering but also extends to various fields such as robotics and aerospace technology.The versatility of bimorph structures lies in their ability to convert energy from one form to another. For example, in piezoelectric bimorph actuators, mechanical stress can be transformed into electrical energy and vice versa. This property is harnessed in applications like energy harvesting, where ambient vibrations are converted into usable electrical power. Such innovations highlight the importance of understanding the fundamental principles behind bimorph designs.Moreover, the study of bimorph materials opens up avenues for creating smart materials that respond dynamically to environmental changes. Researchers are exploring ways to enhance the performance of bimorph structures by incorporating advanced materials such as shape memory alloys or polymer composites. These developments could lead to breakthroughs in creating more efficient and responsive systems across various industries.In addition to their technical applications, bimorph structures also inspire artistic endeavors. Artists and designers have begun to experiment with bimorph concepts in creating kinetic sculptures that move in response to environmental stimuli. This intersection of art and science showcases how the principles of bimorph technology can transcend traditional boundaries, leading to innovative forms of expression.As we continue to explore the potential of bimorph technologies, it is essential to consider the implications of their use. The integration of bimorph materials into everyday products raises questions about sustainability and environmental impact. Engineers and designers must strive to create solutions that not only leverage the advantages of bimorph structures but also prioritize eco-friendly practices. By doing so, we can ensure that the advancements in bimorph technology contribute positively to society and the environment.In conclusion, the concept of bimorph embodies a rich interplay between material properties, engineering principles, and creative expression. As we delve deeper into the study and application of bimorph structures, we unlock new possibilities that can greatly enhance our technological capabilities. Whether through practical applications in engineering or inspiring works of art, the future of bimorph technology holds exciting prospects that could shape the way we interact with the world around us.

在材料科学和工程领域,术语bimorph指的是由两种不同材料组成的结构。这些材料通常因其对比特性而被选择,例如热膨胀或电导率。这两层之间的相互作用使得bimorph表现出独特的行为,使其成为研究和应用的迷人主题。例如,bimorph致动器通常用于需要精确运动的设备,如打印机和传感器。当施加电流时,一层膨胀而另一层收缩,导致整个结构弯曲。这个原理不仅适用于工程,还扩展到机器人技术和航空航天技术等多个领域。bimorph结构的多功能性在于它们能够将一种形式的能量转换为另一种形式。例如,在压电bimorph致动器中,机械应力可以转化为电能,反之亦然。这一特性被用于能量采集等应用中,其中环境振动被转换为可用的电力。这些创新突显了理解bimorph设计基本原理的重要性。此外,研究bimorph材料为创造能够动态响应环境变化的智能材料开辟了新的途径。研究人员正在探索通过结合先进材料如形状记忆合金或聚合物复合材料来增强bimorph结构的性能。这些发展可能会导致在各个行业创造更高效、更具响应性的系统的突破。除了技术应用,bimorph结构还激发了艺术创作的努力。艺术家和设计师开始实验bimorph概念,在创造能够响应环境刺激的动力雕塑方面进行探索。这种艺术与科学的交汇展示了bimorph技术原理如何超越传统界限,带来创新的表达形式。随着我们继续探索bimorph技术的潜力,考虑其使用的影响至关重要。将bimorph材料整合到日常产品中引发了关于可持续性和环境影响的问题。工程师和设计师必须努力创造解决方案,不仅利用bimorph结构的优势,而且优先考虑环保实践。通过这样做,我们可以确保在bimorph技术的进步对社会和环境产生积极影响。总之,bimorph的概念体现了材料特性、工程原理和创意表达之间的丰富互动。随着我们深入研究和应用bimorph结构,我们解锁了许多新可能性,这些可能性可以大大增强我们的技术能力。无论是通过工程中的实际应用,还是通过激励艺术作品,bimorph技术的未来都蕴含着令人兴奋的前景,这些前景可能会影响我们与周围世界的互动方式。